WIDE BAND METAMATERIAL ABSORBER WITH LUMPED ELEMENT
Yıl 2021,
Cilt: 4 Sayı: 1, 61 - 66, 30.06.2021
Hüseyin Korkmaz
,
Uğurcem Hasar
Öz
Many researchers take attention to the significance of harvesting energy from electromagnetic radiation to use in sensor networks. The purpose of this study is to design and analysis of a metamaterial absorber that has the ability to absorb energy in the microwave frequency band with perfect absorption. The results show that the proposed design is a good candidate for supply power from electromagnetic waves to sensor networks.
Kaynakça
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- 8. Singh, G., Marwaha, A. (2015). A review of metamaterials and its applications.
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- 12. Dincer, F., Karaaslan, M., & Sabah, C. (2015). Design and analysis of perfect metamaterial absorber in GHz and THz frequencies. Journal of Electromagnetic Waves and Applications, 29(18), 2492-2500.
- 13. Karaaslan, M., Ba˘gmancı, M., Ünal, E., Akgol, O., & Sabah, C. (2017). Microwave energy harvesting based on metamaterial absorbers with multi-layered square split rings for wireless communications. Optics Communications, 392, 31-38.
- 14. Obaidullah, M., Esat, V., & Sabah, C. (2017). Thin film (6, 5) semiconducting single-walled carbon nanotube metamaterial absorber for photovoltaic applications. Optical Engineering, 56(12), 127101.
- 15. Rufangura, P., & Sabah, C. (2015). Dual-band perfect metamaterial absorber for solar cell applications. Vacuum, 120, 68-74
Yıl 2021,
Cilt: 4 Sayı: 1, 61 - 66, 30.06.2021
Hüseyin Korkmaz
,
Uğurcem Hasar
Kaynakça
- 1. Shaikh, F. K., & Zeadally, S. (2016). Energy harvesting in wireless sensor networks: A comprehensive review. Renewable and Sustainable Energy Reviews, 55, 1041-1054.
- 2. Read, S., Lindhult, E., & Mashayekhi, A. (2016). The Inefficiencies of Energy Efficiency: Reviewing the Strategic Role of Energy Efficiency and its Effectiveness in Alleviating Climate Change. Journal of Settlements and Spatial Planning, 2016(Spec. Iss. 5), 77-87.
- 3. Van de Graaf, T., & Sovacool, B. K. (2020). Global Energy Politics. John Wiley & Sons.
- 4. Feng, L., Huo, P., Liang, Y., & Xu, T. (2019). Photonic Metamaterial Absorbers: Morphology Engineering and Interdisciplinary Applications. Advanced Materials, 1903787.
- 5. Kasap, S., Capper, P. (Eds.). (2017). Springer handbook of electronic and photonic materials. Springer.
- 6. Ahamed, E., Faruque, M. R. I., Mansor, M. F. B., & Islam, M. T. (2019). Polarization-dependent tunneled metamaterial structure with enhanced fields properties for X-band application. Results in Physics, 15, 102530.
- 7. Landy, N. I., Sajuyigbe, S., Mock, J. J., Smith, D. R., & Padilla, W. J. (2008). Perfect metamaterial absorber. Physical review letters, 100(20), 207402.
- 8. Singh, G., Marwaha, A. (2015). A review of metamaterials and its applications.
- 9. Al-badri, K. S. L. (2018). Electromagnetic broad band absorber based on metamaterial and lumped resistance. Journal of King Saud University-Science.
- 10. Dincer, F. (2015). Electromagnetic energy harvesting application based on tunable perfect metamaterial absorber. Journal of Electromagnetic Waves and Applications, 29(18), 2444-2453.
- 11. Gunduz, O. T., & Sabah, C. (2016). Polarization angle independent perfect multiband metamaterial absorber and energy harvesting application. Journal of Computational Electronics, 15(1), 228-238.
- 12. Dincer, F., Karaaslan, M., & Sabah, C. (2015). Design and analysis of perfect metamaterial absorber in GHz and THz frequencies. Journal of Electromagnetic Waves and Applications, 29(18), 2492-2500.
- 13. Karaaslan, M., Ba˘gmancı, M., Ünal, E., Akgol, O., & Sabah, C. (2017). Microwave energy harvesting based on metamaterial absorbers with multi-layered square split rings for wireless communications. Optics Communications, 392, 31-38.
- 14. Obaidullah, M., Esat, V., & Sabah, C. (2017). Thin film (6, 5) semiconducting single-walled carbon nanotube metamaterial absorber for photovoltaic applications. Optical Engineering, 56(12), 127101.
- 15. Rufangura, P., & Sabah, C. (2015). Dual-band perfect metamaterial absorber for solar cell applications. Vacuum, 120, 68-74